about
Addition of allochthonous fungi to a historically contaminated soil affects both remediation efficiency and bacterial diversity.Mobilizing agents enhance fungal degradation of polycyclic aromatic hydrocarbons and affect diversity of indigenous bacteria in soil.Pyrosequencing reveals the effect of mobilizing agents and lignocellulosic substrate amendment on microbial community composition in a real industrial PAH-polluted soil.Implications of polluted soil biostimulation and bioaugmentation with spent mushroom substrate (Agaricus bisporus) on the microbial community and polycyclic aromatic hydrocarbons biodegradation.Effect of additives on enzyme-catalyzed polymerization of phenols and aromatic amines.Bioremediation of long-term PCB-contaminated soil by white-rot fungi.Screening, isolation, and characterization of glycosyl-hydrolase-producing fungi from desert halophyte plants.Comparative assessment of fungal augmentation treatments of a fine-textured and historically oil-contaminated soil.Panus tigrinus efficiently removes phenols, color and organic load from olive-mill wastewater.Characterization of Pleurotus ostreatus biofilms by using the calgary biofilm device.Role of autochthonous filamentous fungi in bioremediation of a soil historically contaminated with aromatic hydrocarbons.An efficient PAH-degrading Lentinus (Panus) tigrinus strain: effect of inoculum formulation and pollutant bioavailability in solid matrices.Inoculum carrier and contaminant bioavailability affect fungal degradation performances of PAH-contaminated solid matrices from a wood preservation plant.In vivo and in vitro polycyclic aromatic hydrocarbons degradation by Lentinus (Panus) tigrinus CBS 577.79.Olive-mill wastewaters: a promising substrate for microbial lipase production.The biodegradation of recalcitrant effluents from an olive mill by a white-rot fungus.Solid-state cultures of Fusarium oxysporum transform aromatic components of olive-mill dry residue and reduce its phytotoxicity.Submerged and solid-state production of laccase and Mn-peroxidase by Panus tigrinus on olive mill wastewater-based media.Reduction of the phenolic components in olive-mill wastewater by an enzymatic treatment and its impact on durum wheat (Triticum durum Desf.) germinability.Chlorobenzoic acid degradation by Lentinus (Panus) tigrinus: in vivo and in vitro mechanistic study-evidence for P-450 involvement in the transformation.Pleurotus ostreatus biofilms exhibit higher tolerance to toxicants than free-floating counterparts.Assessment of olive-mill wastewater as a growth medium for lipase production by Candida cylindracea in bench-top reactor.Immobilized inocula of white-rot fungi accelerate both detoxification and organic matter transformation in two-phase dry olive-mill residue.Kinetic and redox properties of MnP II, a major manganese peroxidase isoenzyme from Panus tigrinus CBS 577.79.Short-term impact of dry olive mill residue addition to soil on the resident microbiota.Fungal Community Structure and As-Resistant Fungi in a Decommissioned Gold Mine Site.Degradation of aromatic hydrocarbons by white-rot fungi in a historically contaminated soil.Bioconversion of olive-mill dry residue by Fusarium lateritium and subsequent impact on its phytotoxicity.An assessment of the relative contributions of redox and steric issues to laccase specificity towards putative substrates.Impact of the Fenton-like treatment on the microbial community of a diesel-contaminated soil.Production, purification and partial characterisation of a novel laccase from the white-rot fungus Panus tigrinus CBS 577.79.Enzyme and fungal treatments and a combination thereof reduce olive mill wastewater phytotoxicity on Zea mays L. seeds.Assessment of degradation potential of aliphatic hydrocarbons by autochthonous filamentous fungi from a historically polluted clay soil.A sustainable use of Ricotta Cheese Whey for microbial biodiesel productionComparative assessment of bioremediation approaches to highly recalcitrant PAH degradation in a real industrial polluted soilLentinus (Panus) tigrinus augmentation of a historically contaminated soil: Matrix decontamination and structure and function of the resident bacterial communityLeaching and microbial treatment of a soil contaminated by sulphide ore ashes and aromatic hydrocarbonsThe reactivity of phenolic and non-phenolic residual kraft lignin model compounds with Mn(II)-peroxidase from Lentinula edodesOxirane-immobilized Lentinula edodes laccase: stability and phenolics removal efficiency in olive mill wastewaterPreparation of Lignin Nanoparticles from Wood Waste for Wood Surface Treatment
P50
Q33297870-D7D4C465-F9B5-4C09-B178-6445C1ACB44AQ33363363-CD0E6D5A-7DA1-4B62-AC1B-7984F79EF488Q35281366-AFA3C166-12BE-4B86-A876-79906658147FQ35463922-E5F615DC-6E29-48E9-99CB-08A96CB19DF7Q38015171-2128E931-E171-4590-8923-D88CB50E6DC0Q39147800-FDAF83D9-CA39-4284-9D2D-561D1ED578C8Q39195621-1C536158-1395-4E2E-B93E-5514BA0A8096Q39739774-8FE188D4-A3C7-4A77-A284-7F7F49F600ECQ40489154-E04A3BB6-E964-4FB6-8221-0925C422C726Q41932168-8D74348F-B634-4FAF-8AC2-0F5180FEAE48Q41955004-A3122B40-8479-4FE5-95A9-ED9421D252C3Q42930217-5F9CA1B7-0A8B-41B5-BD5B-D1AC203CDCEEQ43124872-D6D8FBC1-6182-466E-9C0D-6AB8995E30C7Q43200058-46DF6041-0713-4E44-B0AA-C38F691CDFFCQ43328237-FE5223B4-0115-4AD9-9D72-D16222A3E111Q43333538-BF4CD66D-DA30-41ED-8841-F6297323BAF5Q43342792-175ACBB5-5E41-4A3D-86BB-1DDA82ECBA8EQ43358607-D757C6BD-D4A9-48CD-AF22-246A93FC59CFQ43360241-35883E22-C39D-48FF-900E-E5C436856024Q43361783-EF9F52B7-610B-4BA4-95C9-4EBA1C0948E7Q43363205-0850D161-F0AF-47FA-AA11-E30217E0CA5CQ43368484-FDE689DB-2C70-4585-88E1-8A4580677AFFQ43369193-60C4946C-BCFD-4F1F-A708-FF705F269DF6Q45939137-7ED8320C-3592-4445-B0F9-FF61D2C3497FQ45939979-22A235ED-8AC7-4747-8AA8-57660DFD9C4EQ46255017-8B526802-C015-4F6F-9E2D-307F30691D47Q46461532-9715CC32-4AA8-47B3-81A9-3B7185CC77F7Q46627339-4BCFC633-6C63-4852-B0E6-86EA1E190C59Q46739489-96999632-2967-4C56-9B9A-077088C01A85Q47407321-2D53628A-EA5A-4EC6-932A-D91FFA8CA3E6Q51125466-5AD35D27-A72E-4ED8-A026-8B4BCEF18F15Q51126834-2A8CBCA5-79DD-4671-822D-4C41CA3E45D0Q51503945-827098FE-D48C-4247-8306-DA1A4AAEB3DBQ58115224-5150484F-9479-4425-9C40-15C75F224CF7Q58115453-CF0D75CF-E3C0-4D59-BA88-529BD2AC5DBDQ58115587-DF0F6BBE-13A3-4F9C-BA65-DC24F5A774B4Q58115761-6B83FD21-8C20-461A-9ECC-E9AA7C6677D8Q63400345-E6BA08EF-D1E5-428C-A0C9-70107DE7428BQ63437620-FD0299A8-0C19-49A3-B2A4-A0F0ED5B499AQ64250196-098FEC1F-A4B2-4E28-8CDE-287D78366AB8
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Alessandro D'Annibale
@ast
Alessandro D'Annibale
@en
Alessandro D'Annibale
@es
Alessandro D'Annibale
@nl
type
label
Alessandro D'Annibale
@ast
Alessandro D'Annibale
@en
Alessandro D'Annibale
@es
Alessandro D'Annibale
@nl
prefLabel
Alessandro D'Annibale
@ast
Alessandro D'Annibale
@en
Alessandro D'Annibale
@es
Alessandro D'Annibale
@nl
P1053
F-7225-2010
P106
P1153
7003662309
P21
P31
P3829
P496
0000-0002-4000-663X